Dual-band stereo depth sensing system

ABSTRACT

Methods, systems, and apparatus, including computer programs encoded on a computer storage medium, that determine whether to illuminate a scene with electromagnetic radiation at a first wavelength or electromagnetic radiation at a second wavelength. An illuminator that is configured to selectively emit electromagnetic radiation at the first wavelength and at the second wavelength is triggered to emit electromagnetic radiation at the first wavelength instead of the second wavelength. A first voltage is applied to a first electrically active filter. A third voltage is applied to a second electrically active filter. A first image is obtained from a first sensor that senses electromagnetic radiation that passes through the first filter. A second image is obtained from a second sensor that senses electromagnetic radiation that passes through the second filter. A depth map is generated from the first image and the second image.

BACKGROUND

Electronic devices sometimes include depth-sensing systems. Such adepth-sensing system may enable an electronic device to determinethree-dimensional (3-D) features of an object that is located in frontof the electronic device.

SUMMARY

This document describes techniques, methods, systems, and othermechanisms for provision of a dual-band stereo depth-sensing system. Anexample use of such a system is in a mobile computing device thatutilizes the system to determine 3-D facial features of a person forfacial recognition or face-tracking purposes.

A depth-sensing system may work by emitting electromagnetic radiation(EMR) at a particular wavelength, e.g., a wavelength corresponding toinfrared light, on to a scene and using sensors that capture EMR thatreflects from objects in the scene to determine a depth map of thescene. A scene may refer to what is in a field of view from theperspective of the sensors of the depth-sensing system.

For example, a stereo depth-sensing system may emit EMR at a wavelengthof 850 nm, sense reflections of the emitted EMR off one or more physicalobjects using two sensors, and combine the sensed reflections from thetwo sensors into a depth map. A depth map generated by a depth-sensingsystem may portray distance of portions of the scene from thedepth-sensing system.

Sensors of a depth-sensing system may be more sensitive to a particularwavelength and thus able to more accurately sense depth using EMR atthat particular wavelength. However, the sensors may also be unable todistinguish emitted EMR that is then reflected off objects and EMR thatare ambient to an environment. Accordingly, accuracy of a depth-sensingsystem may depend on environmental conditions. For example, when nosunlight is present, a depth-sensing system using EMR at a wavelength of850 nm may produce more accurate results than a depth-sensing systemusing EMR at a wavelength of 940 nm. However, when sunlight is present,a depth-sensing system using EMR at a wavelength of 850 nm may produceless accurate results than a depth-sensing system using EMR at awavelength of 940 nm.

A dual-band stereo depth-sensing system may combine the advantages ofusing two different wavelengths. For example, a dual-band stereodepth-sensing system may determine that sunlight is being sensed bysensors and, in response, determine to emit and sense EMR at awavelength of 940 nm. In another example, the same dual-band stereodepth-sensing system may determine that sunlight is not being sensed bysensors and, in response, determine to emit and sense using EMR at thewavelength of 940 nm.

An example operation of the dual-band stereo depth-sensing system maybegin with the depth-sensing system receiving an instruction to map thedepth of a scene. In response, the depth-sensing system may analyzesignals received from one or more sensors to determine that a limitedamount of sunlight is present. As such, the depth-sensing system mayselect an operation mode including use of EMR at 850 nm.

In such an operation mode, the depth-sensing system may activate filtersin each of two sensors so that the sensors pass through EMR at 850 nmand attenuate EMR at 940 nm. The depth-sensing system may then triggerits illuminator to output EMR at 850 nm. In such an operation mode, theilluminator may output relatively little EMR at 940 nm (or at least lessEMR at 940 nm than if the depth-sensing system were in a 940 nm EMRoperation mode). The EMR at 850 nm that is output by the illuminator mayradiate into the scene, bounce off objects in the scene, and return tothe two sensors that are activated to pass through such EMR at 850 nm.Each of the two sensors may then capture an image and the computingdevice may compute a depth map from the two images.

Such a system may provide increased accuracy by selecting an optimumwavelength of EMR for certain environmental conditions, all while thesensors may substantially filter out wavelengths other than the selectedwavelength. The selected wavelength of EMR may not be visible to humans,and therefore the depth-sensing system may be able to ensure sufficientillumination of a scene without distracting a human user that may bepresent in the scene. As such, the system may select a preferredwavelength of non-visible EMR based on lighting properties at a givenmoment, and may toggle its illuminator to output and its sensors tosense at the selected wavelength. The system may operate at more thantwo wavelengths (e.g., five different wavelengths specific to differentenvironment properties), and the wavelengths employed may be differentthan those described in this document.

The system may decrease power usage by selecting to emit at an optimumwavelength of EMR for current environmental conditions instead ofemitting EMR at multiple wavelengths. For example, the illuminator maybe capable of simultaneously emitting EMR at 850 nm and at 940 nm usinga corresponding emitter for each wavelength. However, as reflected EMRat the wavelength that is not selected may be substantially filtered outby the sensors, the system may reduce power usage by avoiding emittingEMR at the unselected wavelength while emitting EMR at the selectedwavelength.

Besides accuracy and power, the size and cost of a dual-band stereodepth-sensing system may also be an advantage. The dual-band stereodepth-sensing system may reduce the number of components used togenerate a depth map by using electrically active filters that are ableto selectively attenuate EMR at either 850 nm or 940 nm. Accordingly,instead of using two sensors that sense EMR at 850 nm and two separatesensors that sense EMR at 940 nm, the dual-band stereo depth-sensingsystem may use two sensors that have electrically active filters thatare able to selectively attenuate EMR at 850 nm or 940 nm.

Additionally or alternatively, dual-band stereo depth-sensing system mayuse a rolling shutter sensor instead of a global shutter sensor. Arolling shutter sensor may be physically smaller than a global shuttersensor and may cost less than a global shutter sensor. The dual-bandstereo depth-sensing system may perform a fast readout to reduceartifacts from the rolling shutter sensor. For example, to reducedistortions in moving objects caused by pixel rows being read out atdifferent times, the dual-band stereo depth-sensing system may use afast readout speed of 1/120 of a second instead of 1/30 of a second.

One innovative aspect of the subject matter described in thisspecification is embodied in a device that includes a first sensorincluding a first electrically active filter that is configured to (i)when a first voltage is applied to the first electrically active filter,pass through electromagnetic radiation at a first wavelength andattenuate electromagnetic radiation at a second wavelength, and (ii)when a second voltage is applied to the first electrically activefilter, attenuate electromagnetic radiation at the first wavelength andpass through electromagnetic radiation at the second wavelength, asecond sensor including a second electrically active filter that isconfigured to (i) when a third voltage is applied to the secondelectrically active filter, pass through electromagnetic radiation atthe first wavelength and attenuate electromagnetic radiation at thesecond wavelength, and (ii) when a fourth voltage is applied to thesecond electrically active filter, attenuate electromagnetic radiationat the first wavelength and pass through electromagnetic radiation atthe second wavelength, an illuminator configured to selectively emitelectromagnetic radiation at the first wavelength and at the secondwavelength, and electronic circuitry configured, in response toreceiving an instruction to illuminate a scene and sense the scene withelectromagnetic radiation at the first wavelength, to (a) trigger theilluminator to emit electromagnetic radiation at the first wavelength,(b) apply the first voltage to the first electrically active filter, and(c) apply the third voltage to the second electrically active filter.

Other embodiments of this aspect include corresponding computer systems,apparatus, and computer programs recorded on one or more computerstorage devices, each configured to perform the actions of the methods.A system of one or more computers can be configured to performparticular operations or actions by virtue of having software, firmware,hardware, or a combination of them installed on the system that inoperation causes or cause the system to perform the actions. One or morecomputer programs can be configured to perform particular operations oractions by virtue of including instructions that, when executed by dataprocessing apparatus, cause the apparatus to perform the actions.

The foregoing and other embodiments can each optionally include one ormore of the following features, alone or in combination. For instance,in some aspects the electronic circuitry is configured to obtain a firstimage from the first sensor, obtain a second image from the secondsensor, and generate a depth map from the first image and the secondimage. In some implementations, the electronic circuitry is configuredto determine to illuminate the scene and sense the scene withelectromagnetic radiation at the first wavelength instead ofelectromagnetic radiation at the second wavelength.

In certain aspects, the determining to illuminate the scene and sensethe scene with electromagnetic radiation at the first wavelength insteadof electromagnetic radiation at the second wavelength, includesdetermining that electromagnetic radiation at the second wavelengthsensed by the first sensor satisfies a criterion. In some aspects,determining that electromagnetic radiation at the second wavelengthsensed by the first sensor satisfies a criterion, includes determiningthat an amount of electromagnetic radiation at the second wavelengthsensed by the first sensor is more than an amount of electromagneticradiation at the first wavelength sensed by the first sensor.

In some implementations, determining to illuminate the scene and sensethe scene with electromagnetic radiation at the first wavelength insteadof electromagnetic radiation at the second wavelength, includesdetermining that the device is currently located outdoors. In certainaspects, the electronic circuitry is configured to obtain the firstimage from the first sensor simultaneously with obtaining the secondimage from the second sensor and trigger the illuminator to emitelectromagnetic radiation at the first wavelength in synchrony withobtaining the first image and obtaining the second image.

In some aspects, the illuminator includes a first emitter that isconfigured to emit electromagnetic radiation at the first wavelength anda second emitter that is configured to emit electromagnetic radiation atthe second wavelength. In some implementations, the first sensorincludes a sensing element that is configured to sense electromagneticradiation at both the first wavelength and the second wavelength. Incertain aspects, the sensing element includes a rolling shutter sensingelement. In certain aspects, the first sensor includes a notch filterbetween the sensing element and the first electrically active filter,where the notch filter is configured to attenuate electromagneticradiation at wavelengths between the first wavelength and the secondwavelength. In some implementations the first voltage and the thirdvoltage are the same and the second voltage and the fourth voltage arethe same.

Details of one or more implementations are set forth in the accompanyingdrawings and the description below. Other features, objects, andadvantages will be apparent from the description and drawings, and fromthe claims.

DESCRIPTION OF DRAWINGS

FIGS. 1 and 2 are conceptual diagrams of a dual-band stereodepth-sensing system.

FIG. 3 is a flow diagram that illustrates an example of a process fordual-band stereo depth-sensing.

FIG. 4 is a conceptual diagram of a system that may be used to implementthe systems and methods described in this document.

FIG. 5 is a block diagram of computing devices that may be used toimplement the systems and methods described in this document.

Like reference symbols in the various drawings indicate like elements.

DETAILED DESCRIPTION

FIGS. 1 and 2 are conceptual diagrams of dual-band stereo depth-sensingsystems 100 and 200. The systems 100 and 200 may be the same systemoperating using different wavelengths under different environmentalconditions. FIG. 1 illustrates how the system 100 operates using EMR ata first wavelength under a first set of environmental conditions, e.g.,determining a depth map that indicates facial features of a person 104using 940 nm EMR while in the presence of ambient sunlight from the sun106. FIG. 2 illustrates how the system 200 operates using EMR at asecond different wavelength under a second different set of environmentconditions, e.g., determining a depth map that indicates facial featuresof the person 104 using 850 nm EMR while in the presence of ambientlight from an incandescent light bulb 206.

The systems 100 and 200 may operate using EMR at the first wavelengthunder the first set of environmental conditions, because using the firstwavelength under the first set of environmental conditions may produce amore accurate depth map than using the second wavelength under the firstset of environmental conditions. Conversely, the systems 100 and 200 mayoperate using EMR at the second wavelength under the second set ofenvironmental conditions, because using the second wavelength under thesecond set of environmental conditions may produce a more accurate depthmap than using the first wavelength under the second set ofenvironmental conditions.

For example, when no sunlight is present, a depth-sensing system usingEMR at 850 nm may produce more accurate results than a depth-sensingsystem using EMR at 940 nm. However, when sunlight is present, adepth-sensing system using EMR at 850 nm may produce less accurateresults than a depth-sensing system using EMR at 940 nm.

The systems 100 and 200 may produce more accurate results at 850 nm whensunlight is not present and produce more accurate results at 940 nm whensunlight is present because the systems 100 and 200 may more accuratelysense reflected EMR at 850 nm than EMR at 940 nm, but may be unable todistinguish whether sensed EMR is reflected from EMR that is emitted bythe depth-sensing system or from ambient EMR, e.g., ambient sunlight.

As sunlight includes more EMR at the wavelength of 850 nm than EMR atthe wavelength of 940 nm, the systems 100 and 200 may sense more noisein the form of EMR at 850 nm from sunlight than noise in the form of EMRat 940 nm from sunlight. Accordingly, in the presence of sunlight, thesystems 100 and 200 may produce more accurate depth maps at 940 nm.Conversely, without the presence of sunlight, the systems 100 and 200may produce more accurate depth maps at 850 nm.

In more detail, FIGS. 1 and 2 illustrate a mobile computing device 102that includes an illuminator 110, a first sensor 120A, a second sensor120B, and electronic circuitry 130. The illuminator 110, the firstsensor 120A, the second sensor 120B, and the electronic circuitry 130may be positioned above a display of the mobile computing device 102 asa user views a display from the front, as depicted in FIGS. 1 and 2.

The illuminator 110 includes a first emitter 112A that is configured toemit EMR at a first wavelength and a second emitter 112B that isconfigured to emit EMR at a second wavelength. For example, the firstemitter 112A may be configured to emit much more EMR at 850 nm than EMRat 940 nm and the second emitter 112B may be configured to emit muchmore EMR at 940 nm than EMR at 850 nm. However, alternatively, theilluminator 110 may include a single emitter that is capable ofselectively emitting at the first wavelength and the second wavelength.

The illuminator 110 may selectively emit EMR at the first wavelength orthe second wavelength using the first emitter 112A and the secondemitter 112B in response to instructions from the electronic circuitry130. For example, the illuminator 110 may receive an instruction fromthe electronic circuitry 130 including a bit flag with a value of “0”and, in response, emit EMR at the first wavelength. In another example,the illuminator 110 may receive an instruction from the electroniccircuitry 130 including a bit flag with a value of “1” and, in response,emit EMR at the second wavelength.

The illuminator 110 may include the first emitter 112A and the secondemitter 112B on a single substrate and may include one or more lensesand one or more diffraction optical elements. The one or more lenses andone or more diffraction optical elements may form EMR emitted by thefirst emitter 112A and the second emitter 112B into a particularpattern. For example, the one or more lenses and one or more diffractionoptical elements may form EMR into a grid pattern that is projected ontoa scene.

The first sensor 120A and the second sensor 120B (collectively referredto as sensors 120) may be essentially identical but may be physicallyspaced apart so that different images sensed by the first sensor 120Aand the second sensor 120B may be combined together as part of a stereoview. For example, the first sensor 120A may be positioned onemillimeter to the left of the illuminator 110 and the second sensor 120Bmay be positioned one millimeter to the right of the illuminator 110,where the first sensor 120A, the second sensor 120B, and the illuminator110 are arranged along a single straight line.

The sensors 120 may each include an electrically active filter 122A and122B (collectively referred to as filters 122), respectively. Theelectrically active filter 122A may be configured to attenuate EMR atthe first wavelength less than attenuating EMR at the second wavelengthin response to a first voltage being applied to the electrically activefilter 122A. For example, the electrically active filter 122A may beconfigured to pass through 95% of EMR at the first wavelength and passthrough 2% of EMR at the first wavelength in response to 0.5 volts (V)being applied.

Additionally, the electrically active filter 122A may be configured toattenuate EMR at the first wavelength more than attenuating EMR at thesecond wavelength in response to a second voltage being applied to theelectrically active filter 122A. For example, the electrically activefilter 122A may be configured to pass through 2% of EMR at the firstwavelength and pass through 95% of EMR at the first wavelength inresponse to 1 V being applied.

The electrically active filter 122B may behave similarly to theelectrically active filter 122A, but may transition between filteringstates in response to application of a third voltage instead of a firstvoltage and application of a fourth voltage instead of a second voltage.In some implementations, the third voltage may be the same as the firstvoltage and the fourth voltage may be the same as the second voltage. Insome implementations, the electrically active filters 122 may beFabry-Perrot filters.

The sensors 120 may include sensing elements 124A and 124B (collectivelyreferred to as 124), respectively, that sense EMR that passes throughthe filters 122. For example, the sensing elements 124 may be rollingshutter sensors. In another implementation, the sensing elements 124 maybe global shutter sensors. Rolling shutter sensors may be physicallysmaller and cost less than global shutter sensors. However, rollingshutter sensors may exhibit artifacts from reading out rows of pixels atdifferent times. Accordingly the rolling shutter sensors may beconfigured to use a fast read out to reduce artifacts. For example, therolling shutter sensors may use a read out of 1/120 seconds instead of1/30 seconds. Global shutter sensors may be used in some examples.

The sensors 120 may additionally include a notch filter that attenuatesEMR before the EMR reaches the sensing elements 124. For example, thesensors may include a notch filter between the electrically activefilters 122 and the sensing elements 124. The notch filter may beconfigured to filter out EMR between the first wavelength and the secondwavelength. For example, the notch filter may be configured to attenuate95% of EMR between 860 nm and 930 nm and 2% of EMR at 850 nm and 2% ofEMR at 940 nm.

The sensors 120 may filter and sense in response to instructions fromthe electronic circuitry 130. For example, the sensors 120 may receivean instruction to operate at a first wavelength and, in response, apply0.5 V to the filters 122A. The sensors 120 may then receive aninstruction from the electronic circuitry 130 to read out particularrows of pixels at particular times and, in response, provide dataindicating sensed values for those rows of pixels at the particulartimes.

The electronic circuitry 130 may be configured to control theilluminator 110 and the sensors 120 to generate a depth map of a scene.The electronic circuitry 130 may be entirely in the form of hardware ora combination of hardware and software. For example, the electronicsensor may include one or more processors and one or morecomputer-readable devices that include instructions that, when executedby the one or more processors, cause performance of operations. Incontrolling the illuminator 110 and the sensors 120, the electroniccircuitry 130 may select whether to use a first wavelength or a secondwavelength, and then instruct the illuminator 110 and the sensors 120 touse the first wavelength or the second wavelength.

For example, the electronic circuitry 130 may determine that moreambient EMR at 850 nm is present than ambient EMR at 940 nm and, inresponse, determine to operate at 940 nm. The electronic circuitry 130may then activate the filters 122 in each of the two sensors 120 so thatthe sensors 120 pass through EMR at 940 nm and attenuate EMR at 850 nm.The electronic circuitry 130 may then trigger the illuminator 110 tooutput EMR at 940 nm. The illuminator 110 may output little EMR at 850nm (or at least less EMR at 850 nm than if the system 100 was in an 850nm EMR operation mode). The EMR at 940 nm that is output by theilluminator 110 may radiate into the scene, bounce off objects in thescene, and return to the two sensors 120 that are activated to passthrough such EMR at 940 nm. Each of the two sensors 120 may then capturean image and the electronic circuitry 130 may compute a depth map fromthe two images.

In some implementations, the electronic circuitry 130 may obtain a firstimage from the first sensor 120A simultaneously with obtaining a secondimage from the second sensor 120B and may trigger the illuminator 110 toemit EMR at the first wavelength in synchrony with obtaining the firstimage and obtaining the second image. For example, the electroniccircuitry 130 may trigger the illuminator 110 to emit EMR and thesensors 120 to sense EMR at a same frequency with a same phase.Obtaining the first image and second image simultaneously may ensurethat the first image and second image are corresponding stereo images,because differences in the images may be used by the circuitry toidentify differences in depth. Emitting the EMR in synchrony withsensing images may conserve power by not emitting EMR when the sensorsare not outputting corresponding images.

Additional details regarding operations that may be performed by theelectronic circuitry 130 are discussed below in regards to FIG. 3.

FIG. 1 particularly illustrates how the system 100 may operate at 940 nmin in the presence of more ambient EMR at 850 nm than ambient EMR at 940nm, e.g., ambient EMR from the sun 106. As shown in FIG. 1, theilluminator 110 emits EMR at 940 nm, the filters 122 attenuate ambientEMR at 850 nm and pass through EMR at 940 nm, and the electroniccircuitry then generates a depth map from images sensed by the sensingelements 124 of EMR at 940 nm.

FIG. 2 particularly illustrates how the system 200 may operate at 940 nmin the presence of less ambient EMR at 850 nm than ambient EMR at 940nm, e.g., ambient EMR from an incandescent light bulb 206. As shown inFIG. 2, the illuminator 110 emits EMR at 850 nm, the filters 122attenuate ambient EMR at 940 nm and pass through EMR at 850 nm, and theelectronic circuitry then generates a depth map from images sensed bythe sensing elements 124 of EMR at 850 nm.

FIG. 3 is a flow diagram that illustrates an example of a process 300for dual-band stereo depth-sensing. The operations of the process 300may be performed by one or more electronic circuitry, such as theelectronic circuitry 130 of FIGS. 1 and 2.

The process 300 includes determining whether to illuminate a scene withEMR at a first wavelength or EMR at a second wavelength (310). Forexample, the electronic circuitry 130 may determine to illuminate ascene using either EMR at 850 nm or EMR at 940 nm.

In some implementations, determining whether to illuminate a scene withelectromagnetic radiation at a first wavelength or electromagneticradiation at a second wavelength includes determining whetherelectromagnetic radiation at the second wavelength sensed by the firstsensor satisfies a criteria. For example, the electronic circuitry 130may determine that EMR at 850 nm sensed before the illuminator 110 emitsEMR, i.e., ambient EMR at 850 nm, is above a threshold of three hundredDigital Number (DN) and, in response, determine to illuminate a sceneusing EMR at 940 nm.

In some implementations, determining whether electromagnetic radiationat the second wavelength sensed by the first sensor satisfies a criteriaincludes determining that an amount of electromagnetic radiation at thesecond wavelength sensed by the first sensor is more than an amount ofelectromagnetic radiation at the first wavelength sensed by the firstsensor. For example, the electronic circuitry 130 may determine that EMRsensed at 850 nm before the illuminator 110 emits EMR is two hundred DNwhich is more than an amount of one hundred DN of EMR at 940 nm sensedbefore the illuminator 110 emits EMR and, in response determine toilluminate a scene using EMR at 940 nm.

In some implementations, determining whether electromagnetic radiationat the second wavelength sensed by the first sensor satisfies a criteriaincludes determining that a device including the first sensor isoutdoors. For example, the electronic circuitry 130 may determine that,from global positioning satellite location information and detectedsound from a microphone, the device 102 is outside and, in responsedetermine to illuminate a scene using EMR at 940 nm.

In some implementations, determining whether to illuminate a scene withEMR at a first wavelength or EMR at a second wavelength is performed inresponse to determining to generate a depth map. For example, theelectronic circuitry 130 may determine that a request for a depth maphas been received from another portion of the device 102 and, inresponse, without emitting EMR with the illuminator 110, instruct thesensors 120 to sense EMR at 850 nm, then instruct the sensors 120 tosense EMR at 940 nm, determine whether less EMR was sensed at 850 nm or940 nm, and then select to use the EMR at the wavelength for which lessEMR was sensed.

The process 300 includes triggering an illuminator to emit at a firstwavelength (320). For example, the electronic circuitry 130 may instructthe illuminator 110 to emit EMR at 940 nm using the second emitter 112Bin response to determining to illuminate a scene with EMR at 940 nm.

The process 300 includes applying a first voltage to a firstelectrically active filter (330). For example, the electronic circuitry130 may instruct the sensor 120A to sense at 940 nm or directly apply avoltage of 0.5 V to the filter 122A that causes the filter 122A toattenuate EMR at 850 nm more than the filter 122A attenuates EMR at 940nm.

The process 300 includes applying a third voltage to a secondelectrically active filter (340). For example, the electronic circuitry130 may instruct the sensor 120B to sense at 940 nm or directly apply avoltage of 0.5 V to the filter 122B that causes the filter 122B toattenuate EMR at 850 nm more than the filter 122B attenuates EMR at 940nm.

The process includes obtaining a first image from a first sensor thatsenses EMR that passes through the first filter (350). For example, theelectronic circuitry 130 may receive a sensed image from the sensor120A.

The process includes obtaining a second image from a second sensor thatsenses EMR that passes through the second filter (360). For example, theelectronic circuitry 130 may receive a sensed image from the sensor120B.

The process includes generating a depth map from the first image and thesecond image (370). For example, the electronic circuitry 130 maydetermine portions of the first image and the second image thatcorrespond to the same parts of a scene, determine distances that theparts of the scene are from the sensors, and then generate a depth mapthat indicates the determined distances. Generally, as the sensors 120are physically separated, parts of a scene that are closer to thesensors 120 may be further apart in position from each other between thetwo images and parts of a scene that are further from the sensors 120may be closer to each other in position between the two images.Accordingly, the electronic circuitry 130 may determine a first part ofthe first image corresponds with a second part of the second image,e.g., based on seeing they appear to be similar even though they appearto be in different positions between the image or seeing that they bothinclude the same portion of a grid pattern projected by the illuminator110. The electronic circuitry 130 may then determine a differencebetween a position of the first part from a position of the second part,and then determine a depth of the part of the scene that corresponds tothe difference.

Referring now to FIG. 4, a conceptual diagram of a system that may beused to implement the systems and methods described in this document isillustrated. In the system, mobile computing device 410 can wirelesslycommunicate with base station 440, which can provide the mobilecomputing device wireless access to numerous hosted services 460 througha network 450.

In this illustration, the mobile computing device 410 is depicted as ahandheld mobile telephone (e.g., a smartphone, or an applicationtelephone) that includes a touchscreen display device 412 for presentingcontent to a user of the mobile computing device 410 and receivingtouch-based user inputs. Other visual, tactile, and auditory outputcomponents may also be provided (e.g., LED lights, a vibrating mechanismfor tactile output, or a speaker for providing tonal, voice-generated,or recorded output), as may various different input components (e.g.,keyboard 414, physical buttons, trackballs, accelerometers, gyroscopes,and magnetometers).

Example visual output mechanism in the form of display device 412 maytake the form of a display with resistive or capacitive touchcapabilities. The display device may be for displaying video, graphics,images, and text, and for coordinating user touch input locations withthe location of displayed information so that the device 410 canassociate user contact at a location of a displayed item with the item.The mobile computing device 410 may also take alternative forms,including as a laptop computer, a tablet or slate computer, a personaldigital assistant, an embedded system (e.g., a car navigation system), adesktop personal computer, or a computerized workstation.

An example mechanism for receiving user-input includes keyboard 414,which may be a full qwerty keyboard or a traditional keypad thatincludes keys for the digits ‘0-9’, ‘*’, and ‘#.’ The keyboard 414receives input when a user physically contacts or depresses a keyboardkey. User manipulation of a trackball 416 or interaction with a trackpad enables the user to supply directional and rate of movementinformation to the mobile computing device 410 (e.g., to manipulate aposition of a cursor on the display device 412).

The mobile computing device 410 may be able to determine a position ofphysical contact with the touchscreen display device 412 (e.g., aposition of contact by a finger or a stylus). Using the touchscreen 412,various “virtual” input mechanisms may be produced, where a userinteracts with a graphical user interface element depicted on thetouchscreen 412 by contacting the graphical user interface element. Anexample of a “virtual” input mechanism is a “software keyboard,” where akeyboard is displayed on the touchscreen and a user selects keys bypressing a region of the touchscreen 412 that corresponds to each key.

The mobile computing device 410 may include mechanical or touchsensitive buttons 418 a-d. Additionally, the mobile computing device mayinclude buttons for adjusting volume output by the one or more speakers420, and a button for turning the mobile computing device on or off. Amicrophone 422 allows the mobile computing device 410 to convert audiblesounds into an electrical signal that may be digitally encoded andstored in computer-readable memory, or transmitted to another computingdevice. The mobile computing device 410 may also include a digitalcompass, an accelerometer, proximity sensors, and ambient light sensors.

An operating system may provide an interface between the mobilecomputing device's hardware (e.g., the input/output mechanisms and aprocessor executing instructions retrieved from computer-readablemedium) and software. Example operating systems include ANDROID, CHROME,IOS, MAC OS X, WINDOWS 7, WINDOWS PHONE 7, SYMBIAN, BLACKBERRY, WEBOS, avariety of UNIX operating systems; or a proprietary operating system forcomputerized devices. The operating system may provide a platform forthe execution of application programs that facilitate interactionbetween the computing device and a user.

The mobile computing device 410 may present a graphical user interfacewith the touchscreen 412. A graphical user interface is a collection ofone or more graphical interface elements and may be static (e.g., thedisplay appears to remain the same over a period of time), or may bedynamic (e.g., the graphical user interface includes graphical interfaceelements that animate without user input).

A graphical interface element may be text, lines, shapes, images, orcombinations thereof. For example, a graphical interface element may bean icon that is displayed on the desktop and the icon's associated text.In some examples, a graphical interface element is selectable withuser-input. For example, a user may select a graphical interface elementby pressing a region of the touchscreen that corresponds to a display ofthe graphical interface element. In some examples, the user maymanipulate a trackball to highlight a single graphical interface elementas having focus. User-selection of a graphical interface element mayinvoke a pre-defined action by the mobile computing device. In someexamples, selectable graphical interface elements further oralternatively correspond to a button on the keyboard 404. User-selectionof the button may invoke the pre-defined action.

In some examples, the operating system provides a “desktop” graphicaluser interface that is displayed after turning on the mobile computingdevice 410, after activating the mobile computing device 410 from asleep state, after “unlocking” the mobile computing device 410, or afterreceiving user-selection of the “home” button 418 c. The desktopgraphical user interface may display several graphical interfaceelements that, when selected, invoke corresponding application programs.An invoked application program may present a graphical interface thatreplaces the desktop graphical user interface until the applicationprogram terminates or is hidden from view.

User-input may influence an executing sequence of mobile computingdevice 410 operations. For example, a single-action user input (e.g., asingle tap of the touchscreen, swipe across the touchscreen, contactwith a button, or combination of these occurring at a same time) mayinvoke an operation that changes a display of the user interface.Without the user-input, the user interface may not have changed at aparticular time. For example, a multi-touch user input with thetouchscreen 412 may invoke a mapping application to “zoom-in” on alocation, even though the mapping application may have by defaultzoomed-in after several seconds.

The desktop graphical interface can also display “widgets.” A widget isone or more graphical interface elements that are associated with anapplication program that is executing, and that display on the desktopcontent controlled by the executing application program. A widget'sapplication program may launch as the mobile device turns on. Further, awidget may not take focus of the full display. Instead, a widget mayonly “own” a small portion of the desktop, displaying content andreceiving touchscreen user-input within the portion of the desktop.

The mobile computing device 410 may include one or morelocation-identification mechanisms. A location-identification mechanismmay include a collection of hardware and software that provides theoperating system and application programs an estimate of the mobiledevice's geographical position. A location-identification mechanism mayemploy satellite-based positioning techniques, base station transmittingantenna identification, multiple base station triangulation, internetaccess point IP location determinations, inferential identification of auser's position based on search engine queries, and user-suppliedidentification of location (e.g., by receiving user a “check in” to alocation).

The mobile computing device 410 may include other applications,computing sub-systems, and hardware. A call handling unit may receive anindication of an incoming telephone call and provide a user thecapability to answer the incoming telephone call. A media player mayallow a user to listen to music or play movies that are stored in localmemory of the mobile computing device 410. The mobile device 410 mayinclude a digital camera sensor, and corresponding image and videocapture and editing software. An internet browser may enable the user toview content from a web page by typing in an addresses corresponding tothe web page or selecting a link to the web page.

The mobile computing device 410 may include an antenna to wirelesslycommunicate information with the base station 440. The base station 440may be one of many base stations in a collection of base stations (e.g.,a mobile telephone cellular network) that enables the mobile computingdevice 410 to maintain communication with a network 450 as the mobilecomputing device is geographically moved. The computing device 410 mayalternatively or additionally communicate with the network 450 through aWi-Fi router or a wired connection (e.g., ETHERNET, USB, or FIREWIRE).The computing device 410 may also wirelessly communicate with othercomputing devices using BLUETOOTH protocols, or may employ an ad-hocwireless network.

A service provider that operates the network of base stations mayconnect the mobile computing device 410 to the network 450 to enablecommunication between the mobile computing device 410 and othercomputing systems that provide services 460. Although the services 460may be provided over different networks (e.g., the service provider'sinternal network, the Public Switched Telephone Network, and theInternet), network 450 is illustrated as a single network. The serviceprovider may operate a server system 452 that routes information packetsand voice data between the mobile computing device 410 and computingsystems associated with the services 460.

The network 450 may connect the mobile computing device 410 to thePublic Switched Telephone Network (PSTN) 462 in order to establish voiceor fax communication between the mobile computing device 410 and anothercomputing device. For example, the service provider server system 452may receive an indication from the PSTN 462 of an incoming call for themobile computing device 410. Conversely, the mobile computing device 410may send a communication to the service provider server system 452initiating a telephone call using a telephone number that is associatedwith a device accessible through the PSTN 462.

The network 450 may connect the mobile computing device 410 with a Voiceover Internet Protocol (VoIP) service 464 that routes voicecommunications over an IP network, as opposed to the PSTN. For example,a user of the mobile computing device 410 may invoke a VoIP applicationand initiate a call using the program. The service provider serversystem 452 may forward voice data from the call to a VoIP service, whichmay route the call over the internet to a corresponding computingdevice, potentially using the PSTN for a final leg of the connection.

An application store 466 may provide a user of the mobile computingdevice 410 the ability to browse a list of remotely stored applicationprograms that the user may download over the network 450 and install onthe mobile computing device 410. The application store 466 may serve asa repository of applications developed by third-party applicationdevelopers. An application program that is installed on the mobilecomputing device 410 may be able to communicate over the network 450with server systems that are designated for the application program. Forexample, a VoIP application program may be downloaded from theApplication Store 466, enabling the user to communicate with the VoIPservice 464.

The mobile computing device 410 may access content on the internet 468through network 450. For example, a user of the mobile computing device410 may invoke a web browser application that requests data from remotecomputing devices that are accessible at designated universal resourcelocations. In various examples, some of the services 460 are accessibleover the internet.

The mobile computing device may communicate with a personal computer470. For example, the personal computer 470 may be the home computer fora user of the mobile computing device 410. Thus, the user may be able tostream media from his personal computer 470. The user may also view thefile structure of his personal computer 470, and transmit selecteddocuments between the computerized devices.

A voice recognition service 472 may receive voice communication datarecorded with the mobile computing device's microphone 422, andtranslate the voice communication into corresponding textual data. Insome examples, the translated text is provided to a search engine as aweb query, and responsive search engine search results are transmittedto the mobile computing device 410.

The mobile computing device 410 may communicate with a social network474. The social network may include numerous members, some of which haveagreed to be related as acquaintances. Application programs on themobile computing device 410 may access the social network 474 toretrieve information based on the acquaintances of the user of themobile computing device. For example, an “address book” applicationprogram may retrieve telephone numbers for the user's acquaintances. Invarious examples, content may be delivered to the mobile computingdevice 410 based on social network distances from the user to othermembers in a social network graph of members and connectingrelationships. For example, advertisement and news article content maybe selected for the user based on a level of interaction with suchcontent by members that are “close” to the user (e.g., members that are“friends” or “friends of friends”).

The mobile computing device 410 may access a personal set of contacts476 through network 450. Each contact may identify an individual andinclude information about that individual (e.g., a phone number, anemail address, and a birthday). Because the set of contacts is hostedremotely to the mobile computing device 410, the user may access andmaintain the contacts 476 across several devices as a common set ofcontacts.

The mobile computing device 410 may access cloud-based applicationprograms 478. Cloud-computing provides application programs (e.g., aword processor or an email program) that are hosted remotely from themobile computing device 410, and may be accessed by the device 410 usinga web browser or a dedicated program. Example cloud-based applicationprograms include GOOGLE DOCS word processor and spreadsheet service,GOOGLE GMAIL webmail service, and PICASA picture manager.

Mapping service 480 can provide the mobile computing device 410 withstreet maps, route planning information, and satellite images. Anexample mapping service is GOOGLE MAPS. The mapping service 480 may alsoreceive queries and return location-specific results. For example, themobile computing device 410 may send an estimated location of the mobilecomputing device and a user-entered query for “pizza places” to themapping service 480. The mapping service 480 may return a street mapwith “markers” superimposed on the map that identify geographicallocations of nearby “pizza places.”

Turn-by-turn service 482 may provide the mobile computing device 410with turn-by-turn directions to a user-supplied destination. Forexample, the turn-by-turn service 482 may stream to device 410 astreet-level view of an estimated location of the device, along withdata for providing audio commands and superimposing arrows that direct auser of the device 410 to the destination.

Various forms of streaming media 484 may be requested by the mobilecomputing device 410. For example, computing device 410 may request astream for a pre-recorded video file, a live television program, or alive radio program. Example services that provide streaming mediainclude YOUTUBE and PANDORA.

A micro-blogging service 486 may receive from the mobile computingdevice 410 a user-input post that does not identify recipients of thepost. The micro-blogging service 486 may disseminate the post to othermembers of the micro-blogging service 486 that agreed to subscribe tothe user.

A search engine 488 may receive user-entered textual or verbal queriesfrom the mobile computing device 410, determine a set ofinternet-accessible documents that are responsive to the query, andprovide to the device 410 information to display a list of searchresults for the responsive documents. In examples where a verbal queryis received, the voice recognition service 472 may translate thereceived audio into a textual query that is sent to the search engine.

These and other services may be implemented in a server system 490. Aserver system may be a combination of hardware and software thatprovides a service or a set of services. For example, a set ofphysically separate and networked computerized devices may operatetogether as a logical server system unit to handle the operationsnecessary to offer a service to hundreds of computing devices. A serversystem is also referred to herein as a computing system.

In various implementations, operations that are performed “in responseto” or “as a consequence of” another operation (e.g., a determination oran identification) are not performed if the prior operation isunsuccessful (e.g., if the determination was not performed). Operationsthat are performed “automatically” are operations that are performedwithout user intervention (e.g., intervening user input). Features inthis document that are described with conditional language may describeimplementations that are optional. In some examples, “transmitting” froma first device to a second device includes the first device placing datainto a network for receipt by the second device, but may not include thesecond device receiving the data. Conversely, “receiving” from a firstdevice may include receiving the data from a network, but may notinclude the first device transmitting the data.

“Determining” by a computing system can include the computing systemrequesting that another device perform the determination and supply theresults to the computing system. Moreover, “displaying” or “presenting”by a computing system can include the computing system sending data forcausing another device to display or present the referenced information.

FIG. 5 is a block diagram of computing devices 500, 550 that may be usedto implement the systems and methods described in this document, aseither a client or as a server or plurality of servers. Computing device500 is intended to represent various forms of digital computers, such aslaptops, desktops, workstations, personal digital assistants, servers,blade servers, mainframes, and other appropriate computers. Computingdevice 550 is intended to represent various forms of mobile devices,such as personal digital assistants, cellular telephones, smartphones,and other similar computing devices. The components shown here, theirconnections and relationships, and their functions, are meant to beexamples only, and are not meant to limit implementations describedand/or claimed in this document.

Computing device 500 includes a processor 502, memory 504, a storagedevice 506, a high-speed interface 508 connecting to memory 504 andhigh-speed expansion ports 510, and a low speed interface 512 connectingto low speed bus 514 and storage device 506. Each of the components 502,504, 506, 508, 510, and 512, are interconnected using various busses,and may be mounted on a common motherboard or in other manners asappropriate. The processor 502 can process instructions for executionwithin the computing device 500, including instructions stored in thememory 504 or on the storage device 506 to display graphical informationfor a GUI on an external input/output device, such as display 516coupled to high-speed interface 508. In other implementations, multipleprocessors and/or multiple buses may be used, as appropriate, along withmultiple memories and types of memory. Also, multiple computing devices500 may be connected, with each device providing portions of thenecessary operations (e.g., as a server bank, a group of blade servers,or a multi-processor system).

The memory 504 stores information within the computing device 500. Inone implementation, the memory 504 is a volatile memory unit or units.In another implementation, the memory 504 is a non-volatile memory unitor units. The memory 504 may also be another form of computer-readablemedium, such as a magnetic or optical disk.

The storage device 506 is capable of providing mass storage for thecomputing device 500. In one implementation, the storage device 506 maybe or contain a computer-readable medium, such as a floppy disk device,a hard disk device, an optical disk device, or a tape device, a flashmemory or other similar solid state memory device, or an array ofdevices, including devices in a storage area network or otherconfigurations. A computer program product can be tangibly embodied inan information carrier. The computer program product may also containinstructions that, when executed, perform one or more methods, such asthose described above. The information carrier is a computer- ormachine-readable medium, such as the memory 504, the storage device 506,or memory on processor 502.

The high-speed controller 508 manages bandwidth-intensive operations forthe computing device 500, while the low speed controller 512 manageslower bandwidth-intensive operations. Such allocation of functions is anexample only. In one implementation, the high-speed controller 508 iscoupled to memory 504, display 516 (e.g., through a graphics processoror accelerator), and to high-speed expansion ports 510, which may acceptvarious expansion cards (not shown). In the implementation, low-speedcontroller 512 is coupled to storage device 506 and low-speed expansionport 514. The low-speed expansion port, which may include variouscommunication ports (e.g., USB, Bluetooth, Ethernet, wireless Ethernet)may be coupled to one or more input/output devices, such as a keyboard,a pointing device, a scanner, or a networking device such as a switch orrouter, e.g., through a network adapter.

The computing device 500 may be implemented in a number of differentforms, as shown in the figure. For example, it may be implemented as astandard server 520, or multiple times in a group of such servers. Itmay also be implemented as part of a rack server system 524. Inaddition, it may be implemented in a personal computer such as a laptopcomputer 522. Alternatively, components from computing device 500 may becombined with other components in a mobile device (not shown), such asdevice 550. Each of such devices may contain one or more of computingdevice 500, 550, and an entire system may be made up of multiplecomputing devices 500, 550 communicating with each other.

Computing device 550 includes a processor 552, memory 564, aninput/output device such as a display 554, a communication interface566, and a transceiver 568, among other components. The device 550 mayalso be provided with a storage device, such as a microdrive or otherdevice, to provide additional storage. Each of the components 550, 552,564, 554, 566, and 568, are interconnected using various buses, andseveral of the components may be mounted on a common motherboard or inother manners as appropriate.

The processor 552 can execute instructions within the computing device550, including instructions stored in the memory 564. The processor maybe implemented as a chipset of chips that include separate and multipleanalog and digital processors. Additionally, the processor may beimplemented using any of a number of architectures. For example, theprocessor may be a CISC (Complex Instruction Set Computers) processor, aRISC (Reduced Instruction Set Computer) processor, or a MISC (MinimalInstruction Set Computer) processor. The processor may provide, forexample, for coordination of the other components of the device 550,such as control of user interfaces, applications run by device 550, andwireless communication by device 550.

Processor 552 may communicate with a user through control interface 558and display interface 556 coupled to a display 554. The display 554 maybe, for example, a TFT (Thin-Film-Transistor Liquid Crystal Display)display or an OLED (Organic Light Emitting Diode) display, or otherappropriate display technology. The display interface 556 may compriseappropriate circuitry for driving the display 554 to present graphicaland other information to a user. The control interface 558 may receivecommands from a user and convert them for submission to the processor552. In addition, an external interface 562 may be provide incommunication with processor 552, so as to enable near areacommunication of device 550 with other devices. External interface 562may be provided, for example, for wired communication in someimplementations, or for wireless communication in other implementations,and multiple interfaces may also be used.

The memory 564 stores information within the computing device 550. Thememory 564 can be implemented as one or more of a computer-readablemedium or media, a volatile memory unit or units, or a non-volatilememory unit or units. Expansion memory 574 may also be provided andconnected to device 550 through expansion interface 572, which mayinclude, for example, a SIMM (Single In Line Memory Module) cardinterface. Such expansion memory 574 may provide extra storage space fordevice 550, or may also store applications or other information fordevice 550. Specifically, expansion memory 574 may include instructionsto carry out or supplement the processes described above, and mayinclude secure information also. Thus, for example, expansion memory 574may be provide as a security module for device 550, and may beprogrammed with instructions that permit secure use of device 550. Inaddition, secure applications may be provided via the SIMM cards, alongwith additional information, such as placing identifying information onthe SIMM card in a non-hackable manner.

The memory may include, for example, flash memory and/or NVRAM memory,as discussed below. In one implementation, a computer program product istangibly embodied in an information carrier. The computer programproduct contains instructions that, when executed, perform one or moremethods, such as those described above. The information carrier is acomputer- or machine-readable medium, such as the memory 564, expansionmemory 574, or memory on processor 552 that may be received, forexample, over transceiver 568 or external interface 562.

Device 550 may communicate wirelessly through communication interface566, which may include digital signal processing circuitry wherenecessary. Communication interface 566 may provide for communicationsunder various modes or protocols, such as GSM voice calls, SMS, EMS, orMMS messaging, CDMA, TDMA, PDC, WCDMA, CDMA2000, or GPRS, among others.Such communication may occur, for example, through radio-frequencytransceiver 568. In addition, short-range communication may occur, suchas using a Bluetooth, WiFi, or other such transceiver (not shown). Inaddition, GPS (Global Positioning System) receiver module 570 mayprovide additional navigation- and location-related wireless data todevice 550, which may be used as appropriate by applications running ondevice 550.

Device 550 may also communicate audibly using audio codec 560, which mayreceive spoken information from a user and convert it to usable digitalinformation. Audio codec 560 may likewise generate audible sound for auser, such as through a speaker, e.g., in a handset of device 550. Suchsound may include sound from voice telephone calls, may include recordedsound (e.g., voice messages, music files, etc.) and may also includesound generated by applications operating on device 550.

The computing device 550 may be implemented in a number of differentforms, as shown in the figure. For example, it may be implemented as acellular telephone 580. It may also be implemented as part of asmartphone 582, personal digital assistant, or other similar mobiledevice.

Additionally computing device 500 or 550 can include Universal SerialBus (USB) flash drives. The USB flash drives may store operating systemsand other applications. The USB flash drives can include input/outputcomponents, such as a wireless transmitter or USB connector that may beinserted into a USB port of another computing device.

Various implementations of the systems and techniques described here canbe realized in digital electronic circuitry, integrated circuitry,specially designed ASICs (application specific integrated circuits),computer hardware, firmware, software, and/or combinations thereof.These various implementations can include implementation in one or morecomputer programs that are executable and/or interpretable on aprogrammable system including at least one programmable processor, whichmay be special or general purpose, coupled to receive data andinstructions from, and to transmit data and instructions to, a storagesystem, at least one input device, and at least one output device.

These computer programs (also known as programs, software, softwareapplications or code) include machine instructions for a programmableprocessor, and can be implemented in a high-level procedural and/orobject-oriented programming language, and/or in assembly/machinelanguage. As used herein, the terms “machine-readable medium”“computer-readable medium” refers to any computer program product,apparatus and/or device (e.g., magnetic discs, optical disks, memory,Programmable Logic Devices (PLDs)) used to provide machine instructionsand/or data to a programmable processor, including a machine-readablemedium that receives machine instructions as a machine-readable signal.The term “machine-readable signal” refers to any signal used to providemachine instructions and/or data to a programmable processor.

To provide for interaction with a user, the systems and techniquesdescribed here can be implemented on a computer having a display device(e.g., a CRT (cathode ray tube) or LCD (liquid crystal display) monitor)for displaying information to the user and a keyboard and a pointingdevice (e.g., a mouse or a trackball) by which the user can provideinput to the computer. Other kinds of devices can be used to provide forinteraction with a user as well; for example, feedback provided to theuser can be any form of sensory feedback (e.g., visual feedback,auditory feedback, or tactile feedback); and input from the user can bereceived in any form, including acoustic, speech, or tactile input.

The systems and techniques described here can be implemented in acomputing system that includes a back end component (e.g., as a dataserver), or that includes a middleware component (e.g., an applicationserver), or that includes a front end component (e.g., a client computerhaving a graphical user interface or a Web browser through which a usercan interact with an implementation of the systems and techniquesdescribed here), or any combination of such back end, middleware, orfront end components. The components of the system can be interconnectedby any form or medium of digital data communication (e.g., acommunication network). Examples of communication networks include alocal area network (“LAN”), a wide area network (“WAN”), peer-to-peernetworks (having ad-hoc or static members), grid computinginfrastructures, and the Internet.

The computing system can include clients and servers. A client andserver are generally remote from each other and typically interactthrough a communication network. The relationship of client and serverarises by virtue of computer programs running on the respectivecomputers and having a client-server relationship to each other.

Further to the descriptions above, a user may be provided with controlsallowing the user to make an election as to both if and when systems,programs or features described herein may enable collection of userinformation (e.g., information about a user's social network, socialactions or activities, profession, a user's preferences, or a user'scurrent location), and if the user is sent content or communicationsfrom a server. In addition, certain data may be treated in one or moreways before it is stored or used, so that personally identifiableinformation is removed. For example, a user's identity may be treated sothat no personally identifiable information can be determined for theuser, or a user's geographic location may be generalized where locationinformation is obtained (such as to a city, ZIP code, or state level),so that a particular location of a user cannot be determined. Thus, theuser may have control over what information is collected about the user,how that information is used, and what information is provided to theuser.

Although a few implementations have been described in detail above,other modifications are possible. Moreover, other mechanisms forperforming the systems and methods described in this document may beused. In addition, the logic flows depicted in the figures do notrequire the particular order shown, or sequential order, to achievedesirable results. Other steps may be provided, or steps may beeliminated, from the described flows, and other components may be addedto, or removed from, the described systems. Accordingly, otherimplementations are within the scope of the following claims.

What is claimed is:
 1. A device comprising: a first sensor including afirst electrically active filter that is configured to: (i) when a firstvoltage is applied to the first electrically active filter, pass throughelectromagnetic radiation at a first wavelength and attenuateelectromagnetic radiation at a second wavelength, and (ii) when a secondvoltage is applied to the first electrically active filter, attenuateelectromagnetic radiation at the first wavelength and pass throughelectromagnetic radiation at the second wavelength; a second sensorincluding a second electrically active filter that is configured to: (i)when a third voltage is applied to the second electrically activefilter, pass through electromagnetic radiation at the first wavelengthand attenuate electromagnetic radiation at the second wavelength, and(ii) when a fourth voltage is applied to the second electrically activefilter, attenuate electromagnetic radiation at the first wavelength andpass through electromagnetic radiation at the second wavelength; anilluminator configured to selectively emit electromagnetic radiation atthe first wavelength and at the second wavelength; and electroniccircuitry configured, in response to receiving an instruction toilluminate a scene and sense the scene with electromagnetic radiation atthe first wavelength, to: (a) trigger the illuminator to emitelectromagnetic radiation at the first wavelength, (b) apply the firstvoltage to the first electrically active filter, and (c) apply the thirdvoltage to the second electrically active filter.
 2. The device of claim1, wherein the electronic circuitry is configured to: obtain a firstimage from the first sensor; obtain a second image from the secondsensor; and generate a depth map from the first image and the secondimage.
 3. The device of claim 1, wherein the electronic circuitry isconfigured to: determine to illuminate the scene and sense the scenewith electromagnetic radiation at the first wavelength instead ofelectromagnetic radiation at the second wavelength.
 4. The device ofclaim 3, wherein the determining to illuminate the scene and sense thescene with electromagnetic radiation at the first wavelength instead ofelectromagnetic radiation at the second wavelength, comprises:determining that electromagnetic radiation at the second wavelengthsensed by the first sensor satisfies a criterion.
 5. The device of claim4, wherein determining that electromagnetic radiation at the secondwavelength sensed by the first sensor satisfies a criterion, comprises:determining that an amount of electromagnetic radiation at the secondwavelength sensed by the first sensor is more than an amount ofelectromagnetic radiation at the first wavelength sensed by the firstsensor.
 6. The device of claim 3, wherein determining to illuminate thescene and sense the scene with electromagnetic radiation at the firstwavelength instead of electromagnetic radiation at the secondwavelength, comprises: determining that the device is currently locatedoutdoors.
 7. The device of claim 1, wherein the electronic circuitry isconfigured to: obtain the first image from the first sensorsimultaneously with obtaining the second image from the second sensor;and trigger the illuminator to emit electromagnetic radiation at thefirst wavelength in synchrony with obtaining the first image andobtaining the second image.
 8. The device of claim 1, wherein theilluminator comprises a first emitter that is configured to emitelectromagnetic radiation at the first wavelength and a second emitterthat is configured to emit electromagnetic radiation at the secondwavelength.
 9. The device of claim 1, wherein the first sensor comprisesa sensing element that is configured to sense electromagnetic radiationat both the first wavelength and the second wavelength.
 10. The deviceof claim 9, wherein the sensing element comprises a rolling shuttersensing element.
 11. The device of claim 9, wherein the first sensorcomprises a notch filter between the sensing element and the firstelectrically active filter, wherein the notch filter is configured toattenuate electromagnetic radiation at wavelengths between the firstwavelength and the second wavelength.
 12. The device of claim 1, whereinthe first voltage and the third voltage are the same and the secondvoltage and the fourth voltage are the same.
 13. A computer-implementedmethod, comprising: determining whether to illuminate a scene withelectromagnetic radiation at a first wavelength or electromagneticradiation at a second wavelength; in response to determining toilluminate the scene with electromagnetic radiation at a firstwavelength instead of electromagnetic radiation at a second wavelength:triggering an illuminator that is configured to selectively emitelectromagnetic radiation at the first wavelength and at the secondwavelength to emit electromagnetic radiation at the first wavelengthinstead of the second wavelength; applying a first voltage to a firstelectrically active filter that is configured (i) to pass throughelectromagnetic radiation at the first wavelength and attenuateelectromagnetic radiation at the second wavelength when the firstvoltage is applied to the first electrically active filter, and (ii) toattenuate electromagnetic radiation at the first wavelength and passthrough electromagnetic radiation at the second wavelength when a secondvoltage is applied to the first electrically active filter; applying athird voltage to a second electrically active filter that is configured(i) to pass through electromagnetic radiation at the first wavelengthand attenuate electromagnetic radiation at the second wavelength when athird voltage is applied to the second electrically active filter, and(ii) to attenuate electromagnetic radiation at the first wavelength andpass through electromagnetic radiation at the second wavelength when afourth voltage is applied to the second electrically active filter;obtain a first image from a first sensor that senses electromagneticradiation that passes through the first filter; obtain a second imagefrom a second sensor that senses electromagnetic radiation that passesthrough the second filter; and generate a depth map from the first imageand the second image.
 14. The method of claim 13, wherein determiningwhether to illuminate a scene with electromagnetic radiation at a firstwavelength or electromagnetic radiation at a second wavelength,comprises: determining whether electromagnetic radiation at the secondwavelength sensed by the first sensor satisfies a criteria.
 15. Themethod of claim 14, wherein determining whether electromagneticradiation at the second wavelength sensed by the first sensor satisfiesa criteria comprises: determine that an amount of electromagneticradiation at the second wavelength sensed by the first sensor is morethan an amount of electromagnetic radiation at the first wavelengthsensed by the first sensor.
 16. The method of claim 14, whereindetermining whether electromagnetic radiation at the second wavelengthsensed by the first sensor satisfies a criteria comprises: determiningthat a device including the first sensor is outdoors.
 17. The method ofclaim 13, wherein the first image is obtained from the first sensorsimultaneously with obtaining the second image from the second sensor;and the illuminator is triggered to emit electromagnetic radiation atthe first wavelength in synchrony with obtaining the first image andobtaining the second image.
 18. The method of claim 13, wherein theilluminator comprises a first emitter that is configured to emitelectromagnetic radiation at the first wavelength and a second emitterthat is configured to emit electromagnetic radiation at the secondwavelength.
 19. The method of claim 13, wherein the first sensorcomprises a sensing element that is configured to sense electromagneticradiation at both the first wavelength and the second wavelength.
 20. Anon-transitory computer-readable medium storing instructions executableby one or more computers which, upon such execution, cause the one ormore computers to perform operations comprising: determining whether toilluminate a scene with electromagnetic radiation at a first wavelengthor electromagnetic radiation at a second wavelength; in response todetermining to illuminate the scene with electromagnetic radiation at afirst wavelength instead of electromagnetic radiation at a secondwavelength: triggering an illuminator that is configured to selectivelyemit electromagnetic radiation at the first wavelength and at the secondwavelength to emit electromagnetic radiation at the first wavelengthinstead of the second wavelength; applying a first voltage to a firstelectrically active filter that is configured (i) to pass throughelectromagnetic radiation at the first wavelength and attenuateelectromagnetic radiation at the second wavelength when the firstvoltage is applied to the first electrically active filter, and (ii) toattenuate electromagnetic radiation at the first wavelength and passthrough electromagnetic radiation at the second wavelength when a secondvoltage is applied to the first electrically active filter; applying athird voltage to a second electrically active filter that is configured(i) to pass through electromagnetic radiation at the first wavelengthand attenuate electromagnetic radiation at the second wavelength when athird voltage is applied to the second electrically active filter, and(ii) to attenuate electromagnetic radiation at the first wavelength andpass through electromagnetic radiation at the second wavelength when afourth voltage is applied to the second electrically active filter;obtain a first image from a first sensor that senses electromagneticradiation that passes through the first filter; obtain a second imagefrom a second sensor that senses electromagnetic radiation that passesthrough the second filter; and generate a depth map from the first imageand the second image.